Abstract: In some embodiments, the present application provides an integrated chip (IC). The IC includes a metal-insulator-metal (MIM) device disposed over a substrate. The MIM device includes a plurality of conductive plates that are spaced from one another. The MIM device further includes a first conductive plug structure that is electrically coupled to a first conductive plate and to a third conductive plate of the plurality of conductive plates. A first plurality of insulative segments electrically isolate a second conductive plate and a fourth conductive plate from the first conductive plug structure. The MIM device further includes a second conductive plug structure that is electrically coupled to the second conductive plate and to the fourth conductive plate of the plurality of conductive plates. A second plurality of insulative segments electrically isolate the first conductive plate and the third conductive plate from the second conductive plug structure.

Abstract: According to one example, a device includes a semiconductor substrate. The device further includes a plurality of color filters disposed above the semiconductor substrate. The device further includes a plurality of micro-lenses disposed above the set of color filters. The device further includes a structure that is configured to block light radiation that is traveling towards a region between adjacent micro-lenses. The structure and the color filters are level at respective top surfaces and bottom surfaces thereof.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes an image sensor disposed within a substrate. The substrate has sidewalls and a horizontally extending surface defining one or more trenches extending from a first surface of the substrate to within the substrate. One or more isolation structures are arranged within the one or more trenches. A doped region is arranged within the substrate laterally between sidewalls of the one or more isolation structures and the image sensor and vertically between the image sensor and the first surface of the substrate. The doped region has a higher concentration of a first dopant type than an abutting part of the substrate that extends along opposing sides of the image sensor.

Abstract: The problem of reducing noise in image sensing devices, especially NIR detectors, is solved by providing ground connections for the reflectors. The reflectors may be grounded through vias that couple the reflectors to grounded areas of the substrate. The grounded areas of the substrate may be P+ doped areas formed proximate the surface of the substrate. In particular, the P+ doped areas may be parts of photodiodes. Alternatively, the reflectors may be grounded through a metal interconnect structure formed over the front side of the substrate.

Abstract: The present disclosure relates to an integrated chip including a dielectric structure over a substrate. A first capacitor is disposed between sidewalls of the dielectric structure. The first capacitor includes a first electrode between the sidewalls of the dielectric structure and a second electrode between the sidewalls and over the first electrode. A second capacitor is disposed between the sidewalls. The second capacitor includes the second electrode and a third electrode between the sidewalls and over the second electrode. A third capacitor is disposed between the sidewalls. The third capacitor includes the third electrode and a fourth electrode between the sidewalls and over the third electrode. The first capacitor, the second capacitor, and the third capacitor are coupled in parallel by a first contact on a first side of the first capacitor and a second contact on a second side of the first capacitor.

Abstract: The present disclosure relates to a CMOS image sensor having a multiple deep trench isolation (MDTI) structure, and an associated method of formation. In some embodiments, the image sensor comprises a boundary deep trench isolation (BDTI) structure disposed at boundary regions of a pixel region surrounding a photodiode. The BDTI structure has a ring shape from a top view and two columns surrounding the photodiode with the first depth from a cross-sectional view. A multiple deep trench isolation (MDTI) structure is disposed at inner regions of the pixel region overlying the photodiode, the MDTI structure extending from the back-side of the substrate to a second depth within the substrate smaller than the first depth. The MDTI structure has three columns with the second depth between the two columns of the BDTI structure from the cross-sectional view. The MDTI structure is a continuous integral unit having a ring shape.

Abstract: The present disclosure relates to a CMOS image sensor having a multiple deep trench isolation (MDTI) structure, and an associated method of formation. In some embodiments, the image sensor comprises a plurality of pixel regions disposed within a substrate and respectively comprising a photodiode configured to receive radiation that enters the substrate from a back-side. A boundary deep trench isolation (BDTI) structure is disposed at boundary regions of the pixel regions surrounding the photodiode. The BDTI structure extends from the back-side of the substrate to a first depth within the substrate. A multiple deep trench isolation (MDTI) structure is disposed at inner regions of the pixel regions overlying the photodiode. The MDTI structure extends from the back-side of the substrate to a second depth within the substrate smaller than the first depth. The MDTI structure is a continuous integral unit having a ring shape.

Abstract: In some embodiments, the present disclosure relates to a device having a semiconductor substrate including a frontside and a backside. On the frontside of the semiconductor substrate are a first source/drain region and a second source/drain region. A gate electrode is arranged on the frontside of the semiconductor substrate and includes a horizontal portion, a first vertical portion, and a second vertical portion. The horizontal portion is arranged over the frontside of the semiconductor substrate and between the first and second source/drain regions. The first vertical portion extends from the frontside towards the backside of the semiconductor substrate and contacts the horizontal portion of the gate electrode structure. The second vertical portion extends from the frontside towards the backside of the semiconductor substrate, contacts the horizontal portion of the gate electrode structure, and is separated from the first vertical portion by a channel region of the substrate.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes: a semiconductor substrate including a front surface and a back surface; a backside metallization layer formed over the semiconductor substrate, the backside metallization layer being closer to the back surface than to the front surface of the semiconductor substrate, at least a portion of the backside metallization layer forming an inductor structure; and an electrically non-conductive material formed in the semiconductor substrate, the electrically non-conductive material at least partially overlapping the inductor structure from a top view, and the electrically non-conductive material including a top surface, a bottom surface, and sidewalls, the top surface being adjacent to the back surface of the semiconductor substrate. A method for manufacturing a semiconductor structure is also disclosed.

Abstract: A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, the 3D IC comprises a first IC die comprising a first substrate, a first interconnect structure disposed over the first substrate, and a first through substrate via(TSV) disposed through the first substrate. The 3D IC further comprises a second IC die comprising a second substrate, a second interconnect structure disposed over the second substrate, and a second TSV disposed through the second substrate. The 3D IC further comprises a bonding structure arranged between back sides of the first IC die and the second IC die opposite to corresponding interconnect structures and bonding the first IC die and the second IC die. The bonding structure comprises conductive features disposed between and electrically connecting the first TSV and the second TSV.

Abstract: The present disclosure relates to a semiconductor structure. The semiconductor structure includes a dielectric layer having a first dielectric surface and a second dielectric surface opposite to the first dielectric surface. The dielectric layer defines a recess in the first dielectric surface, and the recess includes a sidewall of the dielectric layer. A first conductive layer contacts a bottom surface of the dielectric layer. The sidewall of the dielectric layer is directly over the first conductive layer. A second conductive layer contacts the first conductive layer and the dielectric layer. The second conductive layer vertically extends from the first conductive layer to above the dielectric layer. A third conductive layer contacts the second conductive layer. The third conductive layer is laterally separated from a sidewall of the second conductive layer that faces the third conductive layer by a non-zero distance.

Abstract: A method for manufacturing three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is formed and bonded to a first IC die by a first bonding structure. A third IC die is formed and bonded to the second IC die by a second bonding structure. The second bonding structure is formed between back sides of the second IC die and the third IC die opposite to corresponding interconnect structures and comprises a first TSV (through substrate via) disposed through a second substrate of the second IC die and a second TSV disposed through a third substrate of the third IC die. In some further embodiments, the second bonding structure is formed by forming conductive features with oppositely titled sidewalls disposed between the first TSV and the second TSV.

Abstract: In some embodiments, the present disclosure relates to a device having a semiconductor substrate including a frontside and a backside. On the frontside of the semiconductor substrate are a first source/drain region and a second source/drain region. A gate electrode is arranged on the frontside of the semiconductor substrate and includes a horizontal portion, a first vertical portion, and a second vertical portion. The horizontal portion is arranged over the frontside of the semiconductor substrate and between the first and second source/drain regions. The first vertical portion extends from the frontside towards the backside of the semiconductor substrate and contacts the horizontal portion of the gate electrode structure. The second vertical portion extends from the frontside towards the backside of the semiconductor substrate, contacts the horizontal portion of the gate electrode structure, and is separated from the first vertical portion by a channel region of the substrate.

Abstract: Present disclosure provides a semiconductor structure, including a semiconductor substrate, a first metal layer, and a through substrate via (TSV). The semiconductor substrate has an active side. The first metal layer is closest to the active side of the semiconductor substrate, and the first metal layer has a first continuous metal feature. The TSV is extending from the semiconductor substrate to the first continuous metal feature. A width of the TSV at the first metal layer is wider than a width of the first continuous metal feature. Present disclosure also provides a method for manufacturing the semiconductor structure described herein.

Abstract: A method for manufacturing an image sensing device includes forming an interconnection layer over a front surface of a semiconductor substrate. A trench is formed to extend from a back surface of the semiconductor substrate. An etch stop layer is formed along the trench. A buffer layer is formed over the etch stop layer. An etch process is performed for etching the buffer layer. The buffer layer and the etch stop layer include different materials.

Abstract: Some embodiments relate an integrated circuit (IC) including a first substrate including a plurality of imaging devices. A second substrate is disposed under the first substrate and includes a plurality of logic devices. A first interconnect structure is disposed between the first substrate and the second substrate and electrically couples imaging devices within the first substrate to one another. A second interconnect structure is disposed between the first interconnect structure and the second substrate, and electrically couples logic devices within the second substrate to one another. A bond pad structure is coupled to a metal layer of the second interconnect structure and extends along inner sidewalls of both the first interconnect structure and the second interconnect structure. An oxide layer extends from above the first substrate to below a plurality of metal layers of the first interconnect structure, and lines inner sidewalls of the bond pad structure.

Abstract: The present disclosure relates to an integrated circuit. The integrated circuit includes a plurality of interconnects within a dielectric structure over a substrate. A passivation structure is arranged over the dielectric structure. The passivation structure has sidewalls connected to one or more upper surfaces of the passivation structure. A bond pad is arranged directly between the sidewalls of the passivation structure. An upper passivation layer is disposed over the passivation structure and the bond pad. The upper passivation layer extends from over an upper surface of the bond pad to within a recess in the upper surface of the bond pad.

Abstract: A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is bonded to a first IC die by a first bonding structure. A third IC die is bonded to the second IC die by a second bonding structure. The second bonding structure is arranged between back sides of the second IC die and the third IC die opposite to corresponding interconnect structures and comprises a first TSV (through substrate via) disposed through a second substrate of the second IC die and a second TSV disposed through a third substrate of the third IC die. The second bonding structure further comprises conductive features with oppositely titled sidewalls disposed between the first TSV and the second TSV.

Abstract: A semiconductor device structure is provided, in some embodiments. The semiconductor device structure includes a semiconductor substrate having a first surface, a second surface, and sidewalls defining a recess that passes through the semiconductor substrate. The semiconductor device structure further includes an interconnect structure having one or more interconnect layers within a first dielectric structure that is disposed along the second surface. A conductive bonding structure is disposed within the recess and includes nickel. The conductive bonding structure has opposing outermost sidewalls that contact sidewalls of the interconnect structure.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes an image sensor disposed within a substrate. The substrate has sidewalls and a horizontally extending surface defining one or more trenches extending from a first surface of the substrate to within the substrate. One or more isolation structures are arranged within the one or more trenches. A doped region is arranged within the substrate laterally between sidewalls of the one or more isolation structures and the image sensor and vertically between the image sensor and the first surface of the substrate. The doped region has a higher concentration of a first dopant type than an abutting part of the substrate that extends along opposing sides of the image sensor.